The invention relates generally to spray coating systems and, more particularly, to an airless spray coating device with a removable valve cartridge.
A typical spray coating device, such as a spray gun, includes a variety of discrete components, such as fluid valves, springs, conduits, and so forth. These discrete components are individually and/or sequentially assembled into a body of the spray coating device. Unfortunately, the discrete nature of these components increases the time and costs associated with manufacture, assembly, maintenance, and cleaning of the spray coating device. If a specific component becomes worn, then the maintenance process can be time consuming and expensive due the numerous discrete components assembled along with the worn component. For example, the coating fluid may eventually wear the components (e.g., valves, seals, etc.) in the fluid path through the spray coating device. Unfortunately, maintenance may involve sequentially removing and replacing a large number of discrete parts, thereby resulting in undesirable downtime. The downtime is particularly undesirably in automated systems, such as assembly lines. Without the maintenance, the spray coating device may produce undesirable spray patterns, non-uniform color distribution, leakage, clogging, and so forth.
A spray coating system, in one embodiment, includes a spray gun having a body, a valve cartridge, and a protective insert. The body includes a passage intersecting a receptacle. The valve cartridge is disposed in the receptacle. The protective insert is disposed in the passage. The protective insert has a central passage, and the protective insert protects the passage from wear by liquid flow through the body.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
One or more specific embodiments of the present invention will be described below. In an effort to provide a concise description of these embodiments, all features of an actual implementation may not be described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
For simplicity, the spray coating device 12 will be described as an airless gun in the following description, although various embodiments of the spray coating device 12 may or may not have a gun-shaped body and/or an airless design. In certain embodiments, the airless gun 12 has a detachable/removable fluid head, which further includes an overhead fluid valve assembly with an integral trigger. The airless gun 12 also may have a body made from one solid piece of material, such as a light aluminum or a light plastic material, featuring a cavity for simple removal of components, such as a valve cartridge. The airless gun 12 may further include components, such as a rotary atomizer, an electrostatic atomizer, or any other suitable spray formation mechanism.
The airless gun 12 may be coupled to a variety of supply and control systems, such as a fluid supply 16 and a control system 20. The control system 20 ensures that the airless gun 12 provides an acceptable quality spray coating on the target object 14. For example, the control system 20 may include an automation system 22, a positioning system 24, a fluid supply controller 26, a computer system 30, and a user interface 32.
The control system 20 also may be coupled to a positioning system 34, which facilitates movement of the target object 14 relative to the airless gun 12. Accordingly, the spray coating system 10 may provide a computer-controlled mixture of coating fluid and spray pattern. Moreover, the positioning system 34 may include a robotic arm controlled by the control system 20, such that the airless gun 12 covers the entire surface of the target object 14 in a uniform and efficient manner.
The spray coating system 10 of
Removable fluid head 204, as will be explained further below, may be detached from cast handle 202 so that a user may interchange removable fluid heads, for example, in situations when it desirable to clean or maintain the replaced fluid head. Alternatively, the detachable feature of fluid head 204 may enable a user to quickly interchange from one spray fluid to another by interchanging fluid heads. In so doing, the replaced fluid head may undergo a thorough cleaning between uses and, thus, be prepared for use in subsequent operations. Still in other situations, the detachable feature of removable head 204 enables a user to quickly replace the fluid head with a similar removable fluid head 204, should the replaced fluid head need maintenance, become damaged or malfunction during operation. Further still, the removable fluid head 204 may be replaced with different types and configurations of fluid heads, such as a rotary spray head, an air-assist spray head, an electrostatic spray head, or a combination thereof.
As mentioned above, cast handle 202 and removable fluid head 204 may be coupled with or decoupled from one another via locking mechanism 206 and 208. Locking mechanisms 206 and 208 may include, for example, cam locks, locking screws and/or locking pins with matching slots, latches, receptacles, and so forth. Locking mechanisms 206 and 208 are adapted to ease the assembly and/or disassembly of cast handle 202 from and/or with removable fluid head 204, respectively. As will be explained further below, airless gun 200 may be conveniently disassembled/or assembled in a manner enabling a user to conveniently interchange and/or replace the removable fluid head, such as removable fluid head 204, of the airless gun 200 during and/or between spray coating operations.
Airless gun 200 further includes a valve cartridge 210, which includes a variety of pre-assembled components for ease of assembly, replacement, maintenance, and so forth. In the illustrated embodiment, the valve cartridge 210 is installed in the removable fluid head 204. More specifically, the valve cartridge 210 may be placed in and removed from a cavity of the removable fluid head 204. The removability of valve cartridge 210 enables the valve cartridge 210 and/or the fluid head 204 to be removed for cleaning and/or maintenance as discussed above. Valve cartridge 210 includes several components that are particularly susceptible to wear by the coating fluid and/or general operation of the airless gun 200. Thus, the pre-assembled nature of the valve cartridge 210 simplifies the installation and removal process, thereby substantially reducing downtime associated with maintenance and repairs. In the illustrated embodiment, valve cartridge 210 includes a valve mechanism, e.g., valve stem 212 coupled to a ball-shaped member 214. Ball member 214 is adapted to close and/or open an aperture through which the coating fluid passes, as airless gun 200 is operated. The components of valve cartridge 210 are discussed and shown in further detail in
Valve cartridge 210 may be actuated overhead by trigger 218, which may be coupled to (or one-piece with) a rotatable lever or trigger body 220. In the illustrated embodiment, trigger 218 and trigger body 220 are one-piece, such that a single structure receives a finger pull from a user in a first direction (e.g., horizontal) and translates this finger pull into a second direction (e.g., vertical or generally crosswise to the first direction) that engages and disengages valve cartridge 210. In other embodiments, trigger 218 and trigger body 220 may form two or more distinct structures coupleable/decoupleable with each other by latching and/or locking mechanisms. Trigger body 220 is adapted to pivot about pivot joint 222 such that moveable press lip 224 presses on valve button 226 to open valve cartridge 210. In other words, the trigger body 220 has first and second portions 220A and 220B disposed about opposite sides of the pivot joint 222, wherein first portion 220A is disposed adjacent a finger grip 218A of trigger 218 and second portion 220B includes press lip 224 disposed adjacent valve cartridge 210. While in the illustrated embodiment press lip 224 may be integrally coupled to trigger body 220 such that those structures form a single structure, other embodiments may include trigger body 220 and press lip 224 as two or more distinct structures coupled together by locking and/or latching mechanisms.
As further illustrated, press lip 224 is disposed directly above valve button 226, which is positioned at the upper portion of valve cartridge 210. As mentioned above, press lip 224 is adapted to press valve button 226 from overhead and, thereby, actuate valve cartridge 210 in an overhead manner. In so doing, valve stem 212 and ball-shaped member 214 move downward, enabling fluid to enter the aperture and flow through airless gun 200. As mentioned above, the structure of valve cartridge 210 may be referred to as an overhead valve assembly due to its placement and actuation generally over or above the fluid conduits within the spray device 200. As will be discussed further below, valve cartridge 210, trigger 218, trigger body 220, pivot 222 and press lip 224 form a mechanism that significantly reduces triggering effort to operate airless gun 200. That is, as a user pulls trigger 218, the transverse motion of trigger 218 applies a torque to trigger body 220 via pivot 222. Accordingly, by pivoting trigger body 220 about pivot joint 222, the transverse motion of the trigger 218 can be efficiently converted to vertical linear motion of valve stem 212. Thus, a user's pull on the trigger 218 can produce a significant amount of vertical force on the valve cartridge 210, thereby making the trigger pull very easy and less burdensome during long periods of operating the airless gun 200. For example, the trigger pull may be less than 3.2 pounds of force with the unique overhead arrangement of the components, including valve cartridge 210.
Airless gun 200 may be coupled to a pressurized spray fluid source via a fluid delivery assembly 228. Fluid delivery assembly 228 may include a fluid inlet tube 230 and a fluid inlet adapter 232. Fluid inlet tube 230 is coupled to fluid inlet adapter 232, which in turn is coupled to a vertical fluid passage 234 disposed at the bottom of removable fluid head 204. Fluid passage 234 is coupled to fluid valve cartridge 210 enabling fluid flow of a pressurized fluid source to removable fluid head 204.
As further illustrated, fluid inlet tube 230 may be coupled to cast handle 202 via attachment 236. In the illustrated embodiment, one end of attachment 236 may be securely attached to cast handle 202 via a screw or bolt 237 fitted in the bottom portion of cast handle 202. The other end of attachment 236 may include a hole through which fluid inlet tube 230 may securely fit. Further, fluid inlet tube 230 may be disposed in relation to cast handle 230 such that the space formed between trigger 218 and fluid inlet tube 230 enables a user to conveniently grip trigger 218. In addition, by partially encompassing trigger 218, fluid inlet tube 230 may define or function as a finger guard as the user holds and/or actuates trigger 218.
Airless gun 200 further includes a fluid spray tip assembly or bell cup 238. The illustrated spray tip assembly 238 includes a fluid delivery tip assembly 240, which includes a flanged portion 241 removably captured in a receptacle 242 between a threaded retention cap 243 and a threaded front portion or cylinder 244 of fluid head 204. For example, cap 243 may capture flanged portion 241 of assembly 240, and then pull it tightly against cylinder 244 as cap 243 threads onto cylinder 244. As illustrated, fluid delivery tip assembly 240 has a cylindrical shape with flanged portion 241 and an internal passage 245, which can be fluidly coupled with fluid passage 246 in cylinder 244. These parts 238, 240, and 244 may be coupled together with a variety of fasteners, such as threaded retention cap 243. For example, assembly 240 may couple directly with assembly 238 via threads, a friction fit, a snap-fit, a slot and key and associated fastener, an annular groove and c-shaped spring fastener, or a combination thereof. A plurality of different types of spray coating devices may be configured to receive and use fluid delivery tip assembly 240. Spray tip assembly 238 may include other components, such as a spray formation assembly configured to define the shape of a spray forming downstream of the airless gun 200.
In certain embodiments, the spray tip assembly 238 may be rotated or twisted to unplug internal orifices in the spray tip assembly 238, the fluid delivery tip assembly 240, or a combination thereof. This twisting unplug motion, in some embodiments, may be applied without unfastening the spray tip assembly 238 from the fluid delivery tip assembly 240. In other words, the spray tip assembly 238 may be free to rotate relative to the fluid delivery tip assembly 240. In addition, the fluid delivery tip assembly 240 may be made of ceramic, tungsten carbide, or a combination thereof. The ceramic and/or tungsten carbide substantially improves the wear resistance of the fluid delivery tip assembly 240. Furthermore, for simplicity in some embodiments, the airless gun 200 may be assembled with a limited number of parts, thereby reducing costs and rendering the gun 200 easier to assemble/disassemble, clean, repair, and so forth. For example, in certain embodiments, the airless gun 200 may be described as consisting of, or consisting essentially of, the dummy handle 202, the removable fluid head 204, the valve cartridge 210, the trigger 218, the fluid delivery tip assembly 240, and the spray tip assembly 238. However, some embodiments may further include a quick connect/disconnect feature between the handle 202 and removable fluid head 204. For example, the quick connect/disconnect feature may include a cam mechanism, a hook and fastener, or another easily attachable and releasable connector such as described above.
As further illustrated, cylinder 244 is disposed directly between fluid tip delivery assembly 240 and valve cartridge 210. Disposed within cylinder 244 is horizontal fluid passage 246 extending from fluid passage 245 in fluid delivery tip assembly 238 to valve cartridge 210. Accordingly, horizontal fluid passage 246 is adapted to deliver spray fluid from valve cartridge 210 to fluid tip delivery assembly 238 when the valve cartridge is in an open position.
The illustrated locking mechanisms 206 and 208 include additional components adapted to lock or disengage fluid head 204 from cast handle 202. In the illustrated embodiment, locking mechanism 206 may include locking member 270, such as a screw and/or a cam lock, disposed within the bottom portion of the cast handle's head 202. Locking member 270 is adapted to move inwardly and outwardly of receptacle 271, such that member 270 can engage receiving member 272 disposed at the bottom portion of removable fluid head 204. Specifically, the illustrated receiving member 272 may have a hook-shaped structure, which includes a hooked end or recess 273 that can be secured by locking member 270 in receptacle 271. Similarly, locking mechanism 208 includes locking member 274 disposed within the upper portion of cast handle 202. Locking member 274 is adapted to engage with receiving member 276 disposed at the upper portion of removable fluid head 204. Accordingly, locking mechanisms 206 and 208 are adapted to integrally fit cast handle 202 and fluid head 204 such that those components may be coupled together to define a single unit. In the illustrated embodiment, locking mechanism 206 is configured to lock cast handle 202 to removable fluid head 204, while locking mechanism 208 may be configured to provide additional support and/or alignment when the aforementioned components of airless gun 200 are assembled.
As further illustrated, during engagement/disengagement of cast handle 202 and fluid head 204, cast handle 202 may be adapted to slide through a central space in trigger 218 so that trigger body 220 and surface 278 of cast handle 202 abut against each other. In so doing, locking mechanisms 206 and 208 and components thereof are aligned, thereby enabling the smooth attachment or detaching of cast handle 202 and fluid head 204.
Further, in some embodiments, trigger 218 may be removable and replaceable so that airless gun 200 may accommodate various trigger sizes. In some embodiments, triggers, such as trigger 218, may be sized so as to accommodate a grip of two or four fingers. Removing trigger 218 from fluid head 204 may be achieved by, for example, first removing pivot joint 222, to which trigger body 220 is coupled, which thereafter enables removing trigger body 220 and trigger 218 as a single unit from removable fluid head 204. Accordingly, in such an embodiment, replacing trigger 218 may constitute replacing trigger body 220 as well. Still in other embodiments, trigger 218 may simply latch off trigger body 220 (using a latching mechanism), thus, enabling fitting removable fluid head 210 with a trigger of a different size.
As mentioned above, the detachment of fluid head 204 from cast handle 202 enables a user to switch fluid heads and/or valve cartridges 210 between operations of airless gun 200. This may be particularly desirable whenever a spray coating job requires applying multiple spray coatings across a surface where each of the spray coatings, such as paint of a particular color, is applied with a different fluid head. Alternatively, the illustrated detachment feature of airless gun 200 may help a user to clean and maintain the airless gun 200 and, particularly, facilitate removal of coating fluid residues deposited in the removable fluid head and valve cartridge 210 during and/or between operations of the airless gun 200. For example, after use, the fluid head 204 and/or valve cartridge 210 may be removed from cast handle 202 and submerged within a cleaning fluid so as to remove the fluid residues, paint stains and so forth. Thereafter, fluid head 204 and/or valve cartridge 210 may be reattached to cast handle 202 and airless gun 200 may be used again with a different spray fluid. Accordingly, unlike spray coating devices which otherwise may require full disassembly for thorough cleaning, removable fluid head 204 and valve cartridge 210 may enable efficiently spraying a surface with a single spray coating device, such as airless gun 200, subsequently applying spray coating fluids.
Further, locking mechanism 404 is formed of a cam arm 410 rotatable about receptacle 412 (e.g., U-shaped receptacle or hook structure) which may be similar to receptacle 292 shown in
Valve cartridge 210 further includes a biasing member, such as spring 422, wound about valve stem 212, such that spring 422 is disposed between valve button 226 and valve body 424. Spring 422 is adapted to balance the force applied to stem valve 212 either from the pressing force applied by press lip 224 or from the force applied by the fluid entering vertical passage 234 into removable fluid head 204, as the press lip 224 is pressed to open and/or close valve cartridge 210. Accordingly, spring 422 and trigger 218 enable the user to conveniently control the opening and closing fluid flow to the fluid head during operation of airless gun 200.
As further illustrated, horizontal fluid passage 246 is disposed within the center of cylinder 244 such that horizontal fluid passage is joined with vertical fluid passage 234 above valve seat 418. Accordingly, horizontal fluid passages 246 and vertical fluid passage 234 meet inside valve cartridge 210, which enables fluid to pass to fluid tip delivery assembly 240.
With reference to
Airless spray gun 250 includes fluid delivery assembly 502, which routes coating fluid to the airless spray gun 250. Airless gun 250 may be coupled to a pressurized spray fluid source via a fluid delivery assembly 502. Fluid delivery assembly 502 may include a fluid inlet tube and an adapter. Fluid delivery assembly 502 is connected to fluid conduit 504 which is located inside the handle of spray gun body 500. Fluid conduit 504 may include a filter to remove particles and other impurities from the coating fluid as it travels through the spray gun handle. In the embodiment, fluid conduit 504 routes the coating fluid to upper fluid conduit 506. Upper fluid conduit 506, in turn, routes the coating fluid to the cartridge fluid conduit 508 which connects the upper fluid conduit 506 to valve cartridge 210. In the illustrated embodiment, conduits 504, 506, and 508 are all integrally formed with the body 500. For example, conduits 504, 506, and 508 may be formed by drilling out passages in body 500 after molding body 500 as discussed above. As further illustrated, the cartridge fluid conduit 508 allows coating fluid to flow in a generally downward direction from the upper fluid conduit 506 into a fluid chamber 512 of cartridge sleeve 510.
In the illustrated embodiment, cartridge sleeve 510 is press-fit into spray gun body 500. However, in alternative embodiments, cartridge sleeve 510 may be threaded, latched, welded, adhered, or otherwise coupled to body 500. When the valve cartridge 210 is open, fluid chamber 512 routes the coating fluid through valve cartridge 210 to the nozzle of the airless spray gun 250. Cartridge sleeve 510 may be composed of any light weight durable material such as an aluminum alloy or a plastic. In the illustrated embodiment, valve cartridge 210 slides into and threadably attaches to the upper portion of valve cartridge sleeve 510. However, in alternative embodiments, valve cartridge 210 may be press-fit, clamped, bolted, or otherwise mounted to the body 500 and/or sleeve 510. The coating fluid flows from sleeve 510 through valve cartridge 210 to a horizontal fluid exit passage 514 which is located inside threaded barrel 516. Threaded barrel 516 is a part of the spray gun body 500. That is, threaded barrel 516 and spray gun body 500 are formed as one piece from the same material. Valve cartridge 210 features a valve which opens and closes, allowing coating fluid to pass through horizontal fluid exit passage 514 to a spray tip assembly (e.g., 238 of
Valve cartridge 210 and its components may be opened and closed by the operator squeezing trigger 518, which is attached to press-lip 520 that contacts the upper portion of valve cartridge 210. Trigger 518 is attached to spray gun body 500 by pivot 522, thereby enabling the press-lip 520 to actuate opening and closing of the valve cartridge 210 in an overhead arrangement similar to
The configuration of valve cartridge 210 in the present embodiment may also be referred to as an overhead valve assembly. Included in valve cartridge 210 is valve button 226, which surrounds at least a portion of spring 422. Spring 422 may be any type of suitable biasing member, such as a coil spring, opposing magnets, pneumatic pressure biased member (e.g., piston-cylinder), resilient material (e.g., rubber), or the like. Spring 422 rests on valve body 424, which features inlet and outlet chambers as well as an aperture for valve stem 212. Seal 252 forms a seal between cartridge sleeve 510 and valve body 424. In operation, seal 252 blocks the coating fluid from reaching spring 422 and button 226. Thus, spring 422 and button 226 remain isolated from the coating fluid. Valve guide 254 fits within valve body 424 and is secured and sealed within valve body 424 by guide seal 256. Valve guide 254 features a cylindrical passage, which valve stem 212 passes through as it moves upward or downward to open or close the overhead valve. Valve seat 418 fits beneath valve guide 254 and is generally composed of a rubber, plastic or other suitable material. The components of valve cartridge 210 may be formed from plastic, rubber, aluminum, stainless steel, or any other suitable durable material. Valve seat 418 also features an aperture for valve stem 212 to pass through. In addition, when valve cartridge 210 is in a closed position, valve stem 212 and ball-shaped member 214 rests against valve seat 418, thereby closing the overhead valve assembly. Valve stem 212 may be threadably attached to valve button 226 in order to actuate the opening or closing of the valve cartridge 210.
As previously discussed, valve cartridge 210 fits inside at least a portion of cartridge sleeve 510. For example, valve cartridge 210 may be threaded into sleeve 510. When the valve assembly is open, fluid may enter valve cartridge sleeve 510 through fluid chamber 512 and exit fluid passage 526. Valve cartridge 210 includes components in the fluid path, thereby resulting in the need for replacement or cleaning over the course of using the spray gun 250. Accordingly, the valve cartridge 210 enables quick removal and replacement of worn components, as the components are all pre-assembled as a self-contained unit. Further, cartridge sleeve 510 may also be removed and/or replaced for cleaning and servicing.
As discussed above with reference to
For example, in the illustrated embodiment, the spray gun body 500 may be made of light weight aluminum, light weight plastic/rubber, or any suitable light weight material, whereas the protective insert 602 and components of the valve cartridge may be made with harder more wear resistant materials (e.g., stainless steel, tungsten carbide, etc.). Body 500 includes a handle and may be formed of a light material, such as a light plastic, a light rubber material, a light metal such as aluminum, a ceramic, or a combination thereof, thereby providing a user with an ergonomic comfortable grip during operation of airless gun 600. Body 500 may be formed by employing a casting or a molding process, whereby molten plastic and/or rubber are poured into a mold conforming body 500 to a desired shape. Thus, the handle has contours that ergonomically fit with a user's hand, while also being a simple one-piece structure.
Airless spray gun 600 includes fluid delivery assembly 502, which routes coating fluid to the airless spray gun 600. Airless gun 600 may be coupled to a pressurized spray fluid source via a fluid delivery assembly 502. Fluid delivery assembly 502 may include a fluid inlet tube and an adapter. Fluid delivery assembly 502 is connected to fluid conduit 504 which is located inside the handle of spray gun body 500. Fluid conduit 504 may include a filter to remove particles and other impurities from the coating fluid as it travels through the spray gun handle. In the embodiment, fluid conduit 504 routes the coating fluid to upper fluid conduit 506. Upper fluid conduit 506, in turn, routes the coating fluid to the cartridge fluid conduit 508 which connects the upper fluid conduit 506 to valve cartridge 210. In the illustrated embodiment, conduits 504, 506, and 508 are all integrally formed with the body 500. For example, conduits 504, 506, and 508 may be formed by drilling out passages in body 500 after molding body 500 as discussed above. As further illustrated, the cartridge fluid conduit 508 allows coating fluid to flow in a generally downward direction from the upper fluid conduit 506 into a fluid chamber 512 of cartridge sleeve 510.
In the illustrated embodiment, cartridge sleeve 510 is press-fit into spray gun body 500. However, in alternative embodiments, cartridge sleeve 510 may be threaded, latched, welded, adhered, or otherwise coupled to body 500. When the valve cartridge 210 is open, fluid chamber 512 routes the coating fluid through valve cartridge 210 to the nozzle of the airless spray gun 600. Cartridge sleeve 510 may be composed of any light weight durable material such as an aluminum alloy or a plastic. In the illustrated embodiment, valve cartridge 210 slides into and threadably attaches to the upper portion of valve cartridge sleeve 510. However, in alternative embodiments, valve cartridge 210 may be press-fit, clamped, bolted, or otherwise mounted to the body 500 and/or sleeve 510. The coating fluid flows from sleeve 510 through valve cartridge 210 to a horizontal fluid exit passage 514 which is located inside threaded barrel 516. Threaded barrel 516 is a part of the spray gun body 500. That is, threaded barrel 516 and spray gun body 500 are formed as one piece from the same material. Valve cartridge 210 features a valve which opens and closes, allowing coating fluid to pass through horizontal fluid exit passage 514 to a spray tip assembly (e.g., 238 of
Valve cartridge 210 and its components may be opened and closed by the operator squeezing trigger 518, which is attached to press-lip 520 that contacts the upper portion of valve cartridge 210. Trigger 518 is attached to spray gun body 500 by pivot 522, thereby enabling the press-lip 520 to actuate opening and closing of the valve cartridge 210 in an overhead arrangement similar to
The configuration of valve cartridge 210 in the present embodiment may also be referred to as an overhead valve assembly. Included in valve cartridge 210 is valve button 226, which surrounds at least a portion of spring 422. Spring 422 may be any type of suitable biasing member, such as a coil spring, opposing magnets, pneumatic pressure biased member (e.g., piston-cylinder), resilient material (e.g., rubber), or the like. Spring 422 rests on valve body 424, which includes an aperture 612 for valve stem 212, an inlet 614, a plurality of circumferential outlets 616, and an internal cavity 618. Seal 252 forms a seal between cartridge sleeve 510 and valve body 424. In operation, seal 252 blocks the coating fluid from reaching spring 422 and button 226. Thus, spring 422 and button 226 remain isolated from the coating fluid. Valve guide 254 fits within the internal cavity 618 of valve body 424 and is secured and sealed within valve body 424 by guide seal 256. Valve guide 254 features a cylindrical passage 620, which valve stem 212 passes through as it moves upward or downward to open or close the overhead valve.
Protective disc 606 fits beneath valve guide 254 to provide wear resistance against fluid flow (e.g., liquid flow) passing into inlet 614 and out through outlets 616 in the valve body 424. As appreciated, the fluid flow directly impacts the protective disc 606, as the fluid flow changes directions by approximately 90 degrees from the inlet 614 to the outlets 618. Thus, the protective disc 606 provides wear resistance to protect the valve guide 254 against the erosive nature of this fluid flow. In certain embodiments, the protective disc 606 is made of a material harder and more wear resistant than the valve guide 254. For example, if the valve guide 254 is made of a plastic or rubber, then the protective disc 606 may be made of a metal, a ceramic, or ceramic metal (i.e., cermet). Likewise, if the valve guide 254 is made of a metal (e.g., aluminum), then the protective disc 606 may be made of a harder metal such as stainless steel, tungsten carbide, or the like. In the illustrated embodiment, the protective disc 606 is a washer having a central passage 622 for the valve stem 212. In other embodiments, the protective disc 606 may be a wear resistant coating applied directly to a surface of the valve guide 254, a cap shaped structure surrounding an end of the valve guide 254, or any other suitable arrangement.
Valve seat 418 fits beneath valve guide 254 and protective disc 606. In the illustrated embodiment, the valve seat 418 may be made with a wear resistant material similar to the protective disc 606. For example, the valve seat 418 may be made with a material harder and more wear resistant than the valve guide 254. For example, if the valve guide 254 is made of a plastic or rubber, then the valve seat 418 may be made of a metal, a ceramic, or ceramic metal (i.e., cermet). Likewise, if the valve guide 254 is made of a metal (e.g., aluminum), then the valve seat 418 may be made of a harder metal such as stainless steel, tungsten carbide, or the like. In other embodiments, the valve seat 418 may include a wear resistant coating that surrounds a relatively softer core structure. In the illustrated embodiment, the valve seat 418 has an annular shaped body with a central passage 624 for the valve stem 212 and a tapered seating surface 626 for the ball shaped member 214. Thus, as the valve stems 212 moves upward and downward through the central passage 624, the ball shaped member 214 engages and disengages the tapered seating surface 626. In the illustrated embodiment, the tapered seating surface 626 may be a conical surface coaxial with an axis 628 of the valve cartridge 210. Furthermore, an angle 630 of the tapered seating surface 626 relative to the axis 628 may be less than approximately 40, 45, 50, or 55 degrees. For example, the angle 630 may range between approximately 30 to 55 degrees, 30 to 40 degrees, or 33 to 35 degrees. In certain embodiments, the angle 630 may be approximately 33 degrees. The angle 630 is selected to provide a tighter wedge fit of the ball shaped member 214 against the tapered seating surface 626, thereby improving the seal and reducing the possibility of leakage. In addition, the tapered seating surface 626 may be machined and polished with a diamond paste to improve the smoothness and sealing performance.
In the illustrated embodiment, the ball-shaped member 214 of the valve stem 212 opens and closes against the tapered seating surface 626 of the valve seat 418. However, in contrast to the embodiment of
As previously discussed, valve cartridge 210 fits inside at least a portion of cartridge sleeve 510. As discussed further below with reference to
As illustrated in
When the valve assembly of valve cartridge 210 is open, the coating fluid may enter upper fluid conduit 506, flow down cartridge fluid conduit 508 to sleeve fluid chamber 512, flow through the passage 624 in valve seat 418, flow through outlets 616, flow though cartridge exit conduit 526, and flow through fluid exit passage 514 to a nozzle assembly (not shown). However, in the illustrated embodiment, the fluid exit passage 514 includes the protective insert 602 disposed in the bore 604. The protective insert 602 is configured to protect the gun barrel 516 against wear by the liquid flow. As discussed above, the protective insert 602 is made of a material harder and more wear resistant that the gun barrel 516. For example, the protective insert may be made with stainless steel, tungsten carbide, or another material relatively harder than the gun barrel 516. Alternatively, the protective insert 602 may be made with any suitable material, and may be considered a removable wear item. In other words, the protective insert 602 may simply prevent wear of the gun barrel 516, while not necessarily being fully resistant to wear. Regardless of the material construction, the protective insert 602 may be a distinct component from the body 500, and may be installed via a press fit, threads, or another suitable mounting technique. In the illustrated embodiment, the protective insert 602 is press fit into the bore 604 in the gun barrel 516. In addition, a radial pin may secure the protective insert 602 in the bore 604 as discussed further below with reference to
As further illustrated in
The illustrated radial diffuser pin 674 extends crosswise through the downstream passage 672. In certain embodiments, the radial diffuser pin 674 may substantially improve internal mixing with the gun barrel 516, while also diffusing the fluid flow in the event of an unintentional target in front of the spray coating device 600. For example, the radial diffuser pin 674 may internally break up and mix the fluid flow for improved spray uniformity downstream. Furthermore, the radial diffuser pin 674 may substantially reduce the impact force, e.g., by at least approximately 20, 25, 30, 35, or 40 percent. Although the illustrated protective insert 602 includes a single radial diffuser pin 674, alternative embodiments may include a plurality of radial diffuser pins 674. For example, the protective insert 602 may include radial diffuser pins 674 at different radial positions, different axial positions, or a combination thereof.
As illustrated, the radial locking pin 696 extends into the gun barrel 516 along one of opposite flats 698 of the gun barrel 516. As a result, the radial locking pin 696 does not interfere with assembly of spray head components with the gun barrel 516. For example, spray head components may couple to the gun barrel 516 via opposite threads 700, while the opposite flats 698 may be gripped with a tool or act as a guide.
As illustrated in
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
This application is a continuation-in-part of U.S. patent application Ser. No. 12/119,133, entitled “AIRLESS SPRAY GUN HAVING A REMOVABLE VALVE CARTRIDGE”, filed on May 12, 2008, which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 12119133 | May 2008 | US |
Child | 12541346 | US |